Sizing and Selection of Control Valves Globe vs. Ball The control valve is the most important single element in any fluid handling system, because it regulates the flow of fluid to the process. To properly select a c ontrol valve, a general knowledge of the process and components is usually necessary. This reference section can help you select and size the control valve that most closely matches the process requirements.
provide an equal percentage flow characteristic, enabling stable control of fluids. Additionally, Additionally, there are more costeffective valve actuators now available for globe valves. Better control and more-competitive pricing now puts globe valves on the same playing field as characterized ball valves.
The sizing of a valve is very important if it is to render good service. If it is undersized, it will not have sufficient capacity. capacity. If it is oversized, the controlled variable may cycle, and the seat, and disc will be subject to wire drawing because of the restricted opening.
Let’s look at a cost comparison as it relates to the decision to select ball or globe valves. For terminal unit applications requiring less than 25 GPM, the globe valve is a more costeffective choice. However, on larger coils the characterized ball valve is the more cost-effective solution.
Systems are designed for the most adverse conditions expected (i.e., coldest weather, greatest load, etc.). In addition, system components (boiler, chiller, pumps, coils, etc.) are limited to sizes available and frequently have a greater capacity than system requirements. Correct sizing of the control valve for actual expected conditions is considered essential for good control.
Technical Comparison Between Globe and Ball Valves Technically, echnically, the globe valve has a stem and plug, which strokes linearly, commonly commonly referred to as “stroke” valves. The ball valve has a stem and ball, which turns horizontally, commonly referred to as “rotational” valves. Early ball valves used a full port opening, allowing large amounts of water to pass through the valve. This gave HVAC HVAC controls contractors the ability ability to select a ball valve two to three pipe sizes smaller than the piping line size. Compared to traditional globe valves that would be only one pipe size smaller than the line s ize, this was often a more cost-effective, device-level solution. In addition, the ball valve could be actuated by a damper actuator, rather than expensive box-style modulating motors.
Pricing Comparison Today, oday, with equivalent pricing between ball and globe valves, the full port ball valve is falling out of favor for most HVAC HVAC control applications. This is also due to its poor installed flow characteristic that leads to its inability to maintain proper control. New “flow optimized” or characterized ball valves, specifically designed for modulating applications, have been been developed. Characterized ball valves are sized the same way as globe valves. They
Most Cost-effective by Applicatio Application n
From a practical standpoint, many jobs will use mostly one type or the other. If the majority of valves on a project tend to be terminal unit valves, then globe valves would offer better control at a lower price. If the majority of the valves are for AHU’s (1-1/4”or larger) characterized characterized Ball Valves Valves are the preferred solution from a pure cost standpoint. Different tolerances to temperature, pressure and steam should also be considered in the selection process.
Selection Guidelines Globe Valve • Lower co cost • Close off of 50 psi or less (typical (typical for most most HVAC HVAC applications) • High High differ different ential ial press pressure ure acros across s valve • Rebuil Rebuildin ding g of the valve valve is is desir desired ed • Better Better contro controll perf perform ormanc ance e • Better Better low low flow flow (partial (partial load) load) performance performance • Use for for steam, steam, water water or wate water/g r/glyc lycol ol media media • Smaller Smaller physical physical profile profile than than a compara comparable ble ball ball valve valve Characterized Ball Valve • Tight Tight shutoff shutoff or high close offs offs of of around around 100 psi* psi* are required • Isolat Isolation ion or or two posi positio tion n contro control** l** • Cv rang ranges es from from 16 to to 250 250 (equates to line sizes 1-1/4” to 2”) • Use for water or water/ water/glycol glycol solution solution only
* This equates to a pump head pressure pressure of approximately approximately 230 ft. Not Not very common common HVAC HVAC applications ** Valve can be line sized to minimize pressure losses; butterfly valves are also used for these applications.
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reference Sizing Pressure Drop for Water Flow A pressure drop must exist across a control valve if flow is to occur. The greater the drop, the greater the flow at any fixed opening. The pressure drop across a valve also varies with the disc position–from minimum when fully open, to 100% of the system drop when fully closed. To size a valve properly, it is necessary to know the full flow pressure drop across it. The pressure drop across a valve is the difference in pressure between the inlet and outlet under flow conditions. When it is specified by the engineer and the required flow is known, the selection of a valve is simplified. When this pressure drop is not known, it must be computed or assumed. If the pressure drop across the valve when fully open is not a large enough percentage of the total sy stem drop, there will be little change in fluid flow until the valve actually closes, forcing the valve’s characteristic toward a quick opening form. Figure 1 shows flow-lift curves for a linear valve with various percentages of design pressure drop. Note the improved characteristic as pressure drop approaches 100% of system pressure drop at full flow. It is important to realize that the flow characteristic for any particular valve, such as the linear c haracteristic shown in Figure 1 is applicable only if the pressure drop remains nearly constant across the valve for full stem travel. In most systems, however, it is impractical to take 100% of the system drop across the valve. A good working rule is, “at maximum flow, 25 to 50% of the total system pressure drop should be absorbed by the control valve.” Although this generally results in larger pump sizes, it should be pointed out that the initial equipment cost is offset by a reduction in control valve size, and results in improved controllability of the system. Reasonably good control can be accomplished with pressure drops of 15 to 30% of total system pressures. A drop of 15% can be used if the variation in flow is small.
Pressure Drop for Steam The same methodology should be applied for selecting a valve for steam where the most important consideration is the pressure drop. First, the correct maximum capacity of the coil must be determined. Ideally, there should be no safety factor in this determination and it should be based on the actual BTU heating requirements. The valve size must be based on the actual supply pressure at the valve. When the valve is fully open, the outlet pressure will assume a value such that the valve capacity and coil condensing rate are in balance. If this outlet valve pressure is relatively large (small pressure drop), then as the valve closes, there will be no appreciable reduction in flow until the valve is nearly closed. To achieve better controllability, the smallest valve (largest pressure drop) should be selected. With the valve outlet pressure much less than the inlet pressure, a large pressure drop results. There will now be an immediate reduction in capacity as the valve throttles. For steam valves, generally the largest possible pressure drop should be taken, without exceeding the critical pressure ratio. Therefore, the steam pressure drop should approach 50% of the absolute inlet pressure. Examining the pressure drops under “Recommended Pressure Drops for Valve Sizing — Steam”, you might be concerned about the steam entering the coil at 0 psig when a large drop is taken across the control valve. Steam flow through the coil will still drop to vacuum pressures due to condensation of the steam. Consequently, a pressure differential will still exist. In this case, proper steam trapping and condensation piping is essential.
Recommended Pressure Drops for Valve Sizing — Water 1. With a differential pressure less than 20 psig, use a pressure drop equal to 5 psi. 2. With a differential pressure greater than 20 psig, use a pressure drop equal to 25% of total system pressure drop (maximum pump head), but not exceeding the maximum rating of the valve.
Figure 1.
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Sizing and Selection of Control Valves Recommended Pressure Drops for Valve Sizing — Steam
Valve Sizing and Selection Example
1. With gravity flow condensate removal and inlet pressure less than 15 psig, use a pressure drop equal to the inlet gauge pressure.
Select a valve to control a chilled water coil that must have a flow of 35 GPM with a valve differential pressure ( P) of 5 psi.
2. With vacuum return system up to 7” Hg vacuum and an inlet pressure less than 2 psig, a pressure drop of 2 psig should be used. With an inlet pressure of 2 to 15 psig, use a pressure drop equal to the inlet gauge pressure.
Determine the valve Cv using the formula for liquids.
3. With an inlet pressure greater than 15 psig, use a pressure drop equal to 50% of inlet absolute pressure. Example: Inlet pressure is 20 psig (35 psia). Use a pressure drop of 17.5 psi.
Select a valve that is suitable for this application and has a Cv as close as possible to the calculated value.
4. When a coil size is selected on the basis that line pressure and temperature is available in the coil of a heating and ventilating application, a very minimum pressure drop is desired. In this c ase, use the following pressure drop:
Initial Pressure
Pressure Drop
15 psi
5 psi
50 psi
7.5 psi
100 psi
10 psi
Over 100 psi
10% of line pressure
The Most Important Variables to Consider When Sizing a Valve: 1. What medium will the valve control? Water? Air? Steam? What effects will specific gravity and viscosity have on the valve size? 2. What will the inlet pressure be under maximum load demand? What is the inlet temperature? 3. What pressure drop (differential) will exist across the valve under maximum load demand? 4. What maximum capacity should the valve handle? 5. What is the maximum pressure differential the valve top must close against? When these are known, a valve can be selected by formula (Cv method) or water and steam capacity tables which can be found in the Valves section of the Master HVAC Products Catalog . The valve size should not exceed the line size, and after proper sizing should preferably be one to two sizes smaller.
88
(continued)
Cv = Q
= 35 GPM
= 15.6
One choice is 277-03186: a 1-1/4” NC valve with a Cv of 16. Refer to Flowrite Valves Reference section.
Valve Selection Criteria 1. Flow characteristic—Modified Equal Percentage which provides good control for a water coil. 2. Body rating and material—Suitable for water plus a metal disc which provides tight shut-off. 3. Valve type and action—A single seat NC valve with an adjustable spring range which can be s equenced with a NO valve used for heating. 4. Valve actuator—Actuator close-off rating is higher than the system P. 5. Valve line size—Its Cv is close to and slightly larger than the calculated Cv (15.6). 6. For Ball Valves—Select a full port valve the same size as the line size for isolation.
reference Full-Port (no flow optimizer) Ball Valve Part Nos. and Flow Coefficients Valve Line Size
Valve Part No.
Effective (Installed) Cv (Kvs) Supply Line Size in Inches (mm)
3/4 (20)
1 (25)
1/2 (15) 599-10208 10.0 (8.62)
7.44 ( 6.41)
6.54 (5.64)
3/4 (20) 599-10210
25.00 20.02 (21.55) (17.26)
in.
1
(mm)
(25) 599-10214
1/2 (13)
1-1/4 (30) 599-10217
63.00 (54.31)
1-1/4 (32)
1-1/2 (38)
2 (51)
2-1/2 (63)
3 (76)
5 (127)
6 (152)
16.08 (13.86) 37.25 32.01 (32.11) (27.59) 100.00 69.84 (86.21) (60.21)
51.72 (44.59)
1-1/2 (40) 599-10219
63.00 62.29 56.29 (54.31) (53.70) (48.53)
1-1/2 (40) 599-10221
160.00 95.87 77.45 (137.93) (82.65) (66.77)
2
(50) 599-10223
100.00 100.00 91.07 (86.21) (86.21) (78.51)
2
(50) 599-10225
250.00 193.94 142.91 (215.52) (167.19) (123.20)
Key
4 (102)
Valve may be oversized. Optimal valve size. Valve may be undersized.
The temperature-pressure ratings for ANSI Classes 125 and 250 valve bodies made of bronze or cast iron are shown below.
Pressure Description Bronze Screwed Bodies Specification #B16.15-1978 ANSI Amer. Std.; USA; ASME
Cast Iron Flanged Bodies Class A-sizes 1 to 12 Specification #B16.1 1975 ANSI Amer. Std.; USA; ASME
Temperature
ANSI Class 125
ANSI Class 250
-20 to + 150°F (-30 to + 66°C)
200 psig (1378 kPa)
400 psig (2758 kPa)
-20 to + 200°F (-30 to + 93°C)
190 psig (1310 kPa)
385 psig (2655 kPa)
-20 to + 250°F (-30 to + 121°C)
180 psig (1241 kPa)
265 psig (2586 kPa)
-20 to + 300°F (-30 to + 149°C)
165 psig (1138 kPa)
335 psig (2300 kPa)
-20 to + 350°F (-30 to + 177°C)
150 psig (1034 kPa)
300 psig (2068 kPa)
-20 to + 400°F (-30 to + 204°C)
125 psig (862 kPa)
250 psig (1724 kPa)
-20 to + 150°F (-30 to + 66°C)
175 psig (1206 kPa)
400 psig (2758 kPa)
-20 to + 200°F (-30 to + 93°C)
165 psig (1138 kPa)
370 psig (2551 kPa)
-20 to + 225°F (-30 to + 106°C)
155 psig (1069kPa)
355 psig (2448 kPa)
-20 to + 250°F (-30 to + 121°C)
150 psig (1034 kPa)
340 psig (2344 kPa)
-20 to + 275°F (-30 to + 135°C)
145 psig (1000 kPa)
325 psig (2241 kPa)
-20 to + 300°F (-30 to + 149°C)
140 psig (965 kPa)
310 psig (2137 kPa)
-20 to + 325°F (-30 to + 163°C)
130 psig (896 kPa)
295 psig (2034 kPa)
-20 to + 350°F (-30 to + 177°C)
125 psig (862 kPa)
280 psig (1931 kPa)
-20 to + 375°F (-30 to + 191°C)
—
265 psig (1827 kPa)
-20 to + 400°F (-30 to + 204°C)
—
250 psig (1734 kPa)
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Sizing and Selection of Control Valves 1. For liquids (water, oil, etc.):
Valve Sizing Formulas The following definitions apply in the following formulas: Cv Valve flow coefficient, U.S. GPM with P = 1 psi
P2 Outlet pressure at maximum flow, psia (abs.) P P1 — P2 at maximum flow, psi Fluid flow, U.S. GPM
Qa Air or gas flow, standard cubic feet per hour (SCFH) at 14.7 psig and 60°F W Steam flow, pounds per hour (lb./hr.) S
Specific gravity of fluid relative to water @ 60°F
G
Specific gravity of gas relative to air at 14.7 psig and 60°F
T
Flowing air or gas temperature (°F)
K
1 + (0.0007 x °F superheat), for steam
V2 Specific volume, cubic feet per pound, at outlet pressure P2 and absolute temperature (T + 460)
2. For gases (air, natural gas, propane, etc.):
Cv=
Qa G(T+460) 1360 P(P2)
Use this when P2 is greater than 1/2P1.
Cv=
Qa G(T+460) 660 P1
Use this when P2 is less than or equal to 1/2P1.
3. For steam (saturated or superheated):
Cv=
WK 2.1 P (P1 + P2)
Cv=
The relationship between kinematic and absolute viscosity: Centistoke =
Centipoise Specific Gravity
Use this for fluids with viscosity correction fact. Use actual specific gravity S for fluids at actual flow temperature.
Cv=Kr Q
Kr Viscosity correction factor for fluids (See Page I-4)
Viscosity Factors
Remarks:
Specific gravity correction is negligible for water below 200°F (use S=1.0). Use actual specific gravity S of other liquids at actual flow temperature.
Cv=Q
P1 Inlet pressure at maximum flow, psia (abs.)
Q
(continued)
Use this when P2 is less than or equal to 1/2P1.
WK 1.82 P1
4. For vapors other than steam:
Cv= 63.4
Use this when P2 is greater than 1/2P1.
WK
When P2 is less than or equal to 1/2P1, use the value of 1/2P1 in place of P and use P2 corresponding to 1/2P1 when determining specific volume V2.
Sizing Formulas and Tables Process Formulas
For Heating Air with Steam Coils:
For Heating or Cooling Water:
lbs. steam/hr. = 1.08 x (°F air temp. rise) x CFM
GPM =
(°F water temp. rise or drop x 500) GPM =
1000
Btu/hr. CFM x .009 x H
For Heating Air with Water Coils: GPM = 2.16 x
formulas °F water temperature change
(H = change in enthalpy of air expressed in Btu/lb. of air)
CFM x (°F air temp. rise)
1000 x (°F water 1 temp. drop)
For Radiation:
For Heating Water with Steam:
lbs. steam/hr. = 0.24 x ft. 2 EDR (Low pressure steam)
lbs. steam/hr. = 0.50 x GPM x (°F water temp. rise)
EDR = Equivalent Direct Radiation
For Heating or Cooling Water:
1 EDR (steam) = 240 BTU/Hr. (Coil Temp. = 215°F)
GPM1 = GPM2 x (°F water 2 temp. rise or drop)
1 EDR (water) = 200 BTU/Hr. (Coil Temp. = 197°F)
& tables °F water 1 temp. drop
90
GPM =
ft.2 EDR 50
(Assume 20°F water TD)
reference Cast Iron Flanges 2-1/2 to 8-inch Cast Iron Flange Dimensions (as defined by ANSI standard B16.1)
ANSI Class 125.
ANSI Class 250.
ANSI Class 125 Flanges Nominal Pipe Size
Drilling
Bolting Number of Bolts
Diameter of Bolts
Length of Machine Bolts
Flange Diameter
Flange Thickness
Diameter of Bolt Circle
Diameter of Bolt Holes
A
B
D
E
2-1/2”
7”
11/16”
5-1/2”
3/4”
4
5/8”
2-1/2”
3”
7-1/2”
3/4”
6”
3/4”
4
5/8”
2-1/2”
4”
9”
15/16”
7-1/2”
3/4”
8
5/8”
3”
5”
10”
15/16”
8-1/2”
7/8”
8
3/4”
3”
6”
11”
1”
9-1/2”
7/8”
8
3/4”
3-1/4”
8”
13-1/2”
1-1/8”
11-3/4”
7/8”
8
7/8”
3-1/2”
F
ANSI Class 250 Flanges Nominal Pipe Size
Drilling
Bolting Number of Bolts
Diameter of Bolts
Length of Machine Bolts
Flange Diameter
Flange Thickness
Diameter of Raised Face
Diameter of Bolt Circle
Diameter of Bolt Holes
A
B
C
D
E
2-1/2”
7-1/2”
1”
4-15/16”
5-7/8”
7/8”
8
3/4”
3-1/4”
3”
8-1/4”
1-1/8”
5-11/16”
6-5/8”
7/8”
8
3/4”
3-1/5”
4”
10”
1-1/4”
6-15/16”
7-7/8”
7/8”
8
3/4”
3-3/4”
5”
11”
1-3/8”
8-5/16”
9-1/4”
7/8”
8
3/4”
4”
6”
12-1/2”
1-7/16”
9-11/16”
10-5/8”
7/8”
12
3/4”
4”
8”
15”
1-5/8”
11-15/16”
13”
1”
12
7/8”
4-1/2”
F
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